U.S. patent number 8,117,970 [Application Number 12/471,905] was granted by the patent office on 2012-02-21 for overhead storage system.
Invention is credited to Michael Baez.
United States Patent |
8,117,970 |
Baez |
February 21, 2012 |
Overhead storage system
Abstract
An overhead storage system includes support beams forming a
frame to a deck around its perimeter and four corner vertical
mounts for suspending the deck from a ceiling. The frame is
preferably made of Z-shaped beams supported by vertical L-shaped
corner supports to provide strong support for a deck. The Z-shaped
beams provide strength and a horizontal surface on which a deck can
be rested. A welded wire deck can be strengthened by bonding it to
ribs. In some embodiments, center supports can preferably be
positioned anywhere along the length of the support beams, and do
not require holes in the beams for mounting. The beams are
preferably connected to the vertical corner brackets without using
threaded fasteners, thereby making the assembly easier for assembly
by a homeowner.
Inventors: |
Baez; Michael (Carlsbad,
CA) |
Family
ID: |
36097567 |
Appl.
No.: |
12/471,905 |
Filed: |
May 26, 2009 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
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11234650 |
Sep 23, 2005 |
7543538 |
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60613037 |
Sep 25, 2004 |
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Current U.S.
Class: |
108/42; 108/149;
211/113 |
Current CPC
Class: |
A47B
96/00 (20130101); E04H 6/42 (20130101) |
Current International
Class: |
A47B
23/00 (20060101) |
Field of
Search: |
;108/42,149,186
;52/30,506.06,764,506.01,506.07 ;211/113,118,119,117,186,153 |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
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640536 |
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May 1962 |
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CA |
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1045379 |
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Oct 1966 |
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GB |
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2045600 |
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Nov 1980 |
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GB |
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2074440 |
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Nov 1981 |
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GB |
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2305597 |
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Apr 1997 |
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GB |
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2327336 |
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Jan 1999 |
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GB |
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8254039 |
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Oct 1996 |
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JP |
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Other References
Office Action mail date in U.S. Appl. No. 12/122,323 to Michael
Baez for Overhead Storage System (7 pgs). cited by other .
Western Pacific Storage Systems, RivetTier Assembly Instructions
for Z-Beam Shelving , assembly instructions, 1998, p. 1, Western
Pacific Storage Systems, US. cited by other .
Office Action for U.S. Appl. No. 11/234,649, by Michael Baez for
Overhead Storage System (7 pgs). cited by other .
Ortho Books, `How to Design and Build Storage Projects`, 1983, p.
78. cited by other .
Web pages from www.parsteel.com, Oct. 7, 2000, 4 pages. cited by
other .
Web pages from www.salcoeng.com, Jan. 25, 1999, 3 pages. cited by
other .
Borroughs Corporation; Rivet-Span Catalog, 12 pages. cited by other
.
RiveTier's Boltless Shelving Instructions, 1 page. cited by other
.
Rapid Rack--`Z` Beam Bulk Shelving Instructions, 1 page. cited by
other .
Grainger's Catalog No. 394, 3 pages. cited by other .
Gorilla Racks Products; Assembly Instructions for Storage
Rack/Workbench, Model GRZ 8460-5; Revision A, 11 pages. cited by
other .
Mecalux; Wide Span Shelving, 8 pages. cited by other.
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Primary Examiner: Chen; Jose V
Attorney, Agent or Firm: Scheinberg & Griner, LLP
Griner; David Burton; Randall W.
Parent Case Text
This application is a continuation of U.S. patent application Ser.
No. 11/234,650 filed Sep. 23, 2005 now U.S. Pat. No. 7,543,538, and
from U.S. Provisional application 60/613,037 filed Sep. 25, 2004,
which are hereby incorporated by reference.
Claims
I claim:
1. A storage system for suspending from an overhead structure,
comprising: a deck for storing items; at least two beams supporting
the deck, each of the at least two beams including a horizontal
flat area on the upper surface of the beam for supporting the deck
and a horizontal flat area on a lower surface of the beam; four
vertical supports for supporting the at least two beams; at least
one center support, the at least one center support being a
vertical support and including an upper portion for attaching to a
ceiling and a lower portion for supporting at least one of the
beams, the lower portion of said center support including a
horizontal flat portion that fits underneath the beam to support
the beam by contact with the horizontal flat area on a lower
surface of the beam; and the center support being positionable at
any point along a continuous portion of at least one of the beams,
the position along the beam not being limited by the location of
particular features along the beam length, thereby providing
additional support to the beam and the deck at a position
determinable by the user; the deck supported by at least two beams
located at opposite ends of the deck, each of the at least two
beams includes including a lip that extends vertically upward from
the horizontal flat area on the upper surface of the beam so that
when the deck is supported by the beams, the deck is held between
the inner surfaces of the opposing lips; and in which at least one
of the two opposing beams is supported by the at least one center
support, the center support being positioned at the outside edge of
the supported beam on the opposite side of the lip of the supported
beam from the deck, with the lower portion of said center support
extending below the lip and supporting the beam.
2. The storage system of claim 1 in which the lip of the beam is
clamped between the vertical portion of the center support and a
clamping member positioned on the opposite side of the lip from the
vertical center support, to sandwich the lip.
3. The storage system of claim 2 in which the clamping member
includes a plate.
4. The storage system of claim 1 in which the four vertical
supports and the at least one center support each comprise an upper
member and a lower member which are adjustably coupled together so
that the length of the vertical and center supports can be manually
adjusted to vary the distance between the deck and the overhead
structure.
5. The storage system of claim 1 in which the at least one beam
includes a horizontal portion extending from a downwardly extending
vertical portion of the beam, said horizontal portion extending
horizontally and inwardly toward the deck from the vertical
portion.
6. The storage system of claim 1 in which the deck includes a wire
deck comprised of a grid of elongate members.
7. The storage system of claim 6 in which at least one of the beams
includes one or more L-shaped clips that extend upward from the
horizontal flat area on the upper surface of the beam to engage at
least one of the elongate members of the wire deck between the
L-shaped clip and the horizontal vertical extending vertically on
the upper surface of the beam, thereby preventing the wire deck
from sliding relative to the frame.
8. The storage system of claim 1 in which the at least one beam
includes a downwardly extending vertical portion, said vertical
portion being below the horizontal flat area on the upper surface
of the beam.
9. A first storage system for suspending from a ceiling comprising:
a deck for storing items, the deck being a wire deck including a
grid of elongate members; four beams forming a rectangular frame
for supporting the deck along its perimeter, the deck not extending
past the outside of the frame, each of the beams including a
horizontal flat area on the upper surface of the beam for
supporting the deck and a horizontal flat area on a lower surface
of the beam, at least one of the beams includes one or more
L-shaped clips that extend upward from the horizontal flat area on
the upper surface of the beam to engage at least one of the
elongate members of the wire deck between the L-shaped clip and the
horizontal vertical extending vertically on the upper surface of
the beam, thereby preventing the wire deck from sliding relative to
the frame; four vertical supports for supporting the four beams,
the vertical supports having an L-shaped cross-section; at least
one center support, the at least one center support being a
vertical support and including an upper portion for attaching to a
ceiling and a lower portion for supporting at least one of the
beams, the lower portion of said center support including a
horizontal flat portion that fits underneath a beam to support the
beam by contact with the horizontal flat area on a lower surface of
the beam; the center support being positionable at any point along
a continuous portion of at least one of the beams, the position
along the beam not being limited by the location of particular
features along the beam length, thereby providing additional
support to the beam and the deck at a position; and mating
connectors allowing each vertical support of said first storage
system to be connected to a vertical support from an additional
storage system mounted on the side of said first storage
system.
10. The storage system of claim 9 in which the multiple vertical
supports and the at least one center support each comprise an upper
member and a lower member which are adjustably coupled together so
that the length of the vertical and center supports can be manually
adjusted to vary the distance between the deck and the overhead
structure.
11. The storage system of claim 9 in which the deck includes a wire
deck comprised of a grid of elongate members.
12. The storage system of claim 9 in which at least one of the
beams includes one or more L-shaped clips that extend upward from
the horizontal flat area on the upper surface of the beam to engage
at least one of the elongate members of the wire deck between the
L-shaped clip and the horizontal vertical extending vertically on
the upper surface of the beam, thereby preventing the wire deck
from sliding relative to the frame.
Description
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an overhead storage system that is
particularly suitable for use in a garage.
BACKGROUND OF THE INVENTION
People store many items besides cars in the garages of their homes
and businesses. Garages tend to collect so much "stuff" that many
people can no longer fit their cars in their garages. One way of
increasing the storage space available in a garage is to use
overhead storage, rather than just using floor space. Several
systems have been designed to provide storage space suspended from
a ceiling.
For example, U.S. Pat. No 6,311,626 to Roberts for a "Hanging
Storage Shelf System" describes a shelf supported by bars, which in
turn are suspended by threaded rods screwed into ceiling
joists.
U.S. Pat. No. 6,435,105 to Mikich et al. for a "Suspended Storage
Structure" describes the use of one or more welded wire frames
connected together to form a shelf for storing items. The welded
wire frame is supported underneath by square tubes on two sides,
and straps attach the square tubes to brackets attached to a
ceiling.
U.S. Pat. No. 6,715,427, also to Mikich et al. for a "Suspended
Storage Structure," describes another storage structure that is
suspended from a ceiling. The system uses one or more welded wire
panels to form a shelf for storing items. The welded wire panels
are supported by transverse support pieces that are attached to
straps, which are in turn connected to a ceiling beam. The shelves
are cantilevered, which reduces the weight that the shelves can
support.
U.S. Pat. No. 6,725,608 to Kraus for a "Garage Overhead Storage
Assembly" describes a storage shelf supported by three "shelf
catching beams" which in turn are supported by metal ties that
extend to "ceiling catching beams" that span the ceiling
joists.
While each of the systems describe above provides suspended
storage, each has disadvantages, such as weight or weight
distribution limits, difficulty in juxtaposing units, construction
costs, or difficulty of assembly by a homeowner. Various
embodiments of the present invention can overcome some or all of
those deficiencies.
SUMMARY OF THE INVENTION
An object of the invention is to provide an overhead storage system
that provides improved suspended storage. The system includes
several novel aspects, not all of which need to be included in
every embodiment.
The invention provides a suspended storage system that, in various
embodiments, can support a relatively large amount of weight, can
be easily assembled from a "do it yourself" kit, can be readily
adjusted to different load distributions, and can be juxtaposed to
form multiple unit assemblies.
Some embodiments use a frame composed of four beams to support a
deck around its perimeter, each beam including a horizontal portion
forming a shelf on which the edge of the deck rests. The frame
provides strength that is not found in the prior art units
described above, and the horizontal portion of the beams provides
stability for the deck. In some embodiments, the frame can have a
generally Z-shaped cross section; in other embodiments the frame
cross section can be L-shaped or C-shaped. In some embodiments, the
frame can be formed from expandable support beams so that the frame
length and/or width can be adjusted.
Preferred Z-shaped beams provide support strength and facilitate
deck attachment. The indentation under the horizontal portion of
the Z-shaped beams and above the angled portion provides a place
where optional center vertical supports can be attached by clamping
them to the beam, thereby allowing center supports to be placed
wherever desired along the length of the frame.
Some embodiments use a welded wire deck, the deck being supported
from below by ribs to which wires of the deck are bonded to provide
stability and sturdiness. Preferred deck support ribs have flat
ends to provide broad support to the wire deck near the frame and
are V-shaped in the center to provide strength along the span away
from the frame. One or more clips can be used to prevent the wire
deck from sliding relative to the frame.
In some embodiments, multiple welded wire deck sections or panels
can be combined to create a larger wire deck, with cross support
ribs perpendicular to the deck support ribs underlying the
intersection of adjacent wire decks and supporting the adjacent
ends of deck support ribs from each wire deck.
Some embodiments can include a net or other structure that can be
affixed so that items on the deck cannot fall off. Some embodiments
can include a retractable shade that can be extended to hide the
contents of the storage system.
The foregoing has outlined rather broadly the features and
technical advantages of the present invention in order that the
detailed description of the invention that follows may be better
understood. Additional features and advantages of the invention
will be described hereinafter. It should be appreciated by those
skilled in the art that the conception and specific embodiment
disclosed may be readily utilized as a basis for modifying or
designing other structures for carrying out the same purposes of
the present invention. It should also be realized by those skilled
in the art that such equivalent constructions do not depart from
the spirit and scope of the invention as set forth in the appended
claims.
BRIEF DESCRIPTION OF THE DRAWINGS
For a more thorough understanding of the present invention, and
advantages thereof, reference is now made to the following
descriptions taken in conjunction with the accompanying drawings,
in which:
FIG. 1 shows a bottom perspective view of a preferred embodiment of
the invention.
FIG. 2 shows a vertical corner support used in the embodiment shown
in FIG. 1.
FIG. 3 shows an end view of a Z-shaped beam used in the embodiment
of FIG. 1.
FIG. 4A shows an L-shaped beam that can be used as an alternative
to the beam in FIG. 3. FIG. 4B shows another embodiment of an
L-shaped beam that can be used as an alternative to the beam in
FIG. 3.
FIG. 5A shows a C-shaped beam that can be used as an alternative to
the beam in FIG. 3. FIG. 5B shows another embodiment of a C-shaped
beam that can be used as an alternative to the beam in FIG. 3.
FIG. 6 shows a cross section of a deck rib taken along the lines
6-6 from FIG. 1.
FIG. 7 shows a Z-beam of FIG. 3 with an L-clip for holding a welded
wire frame.
FIG. 8 shows a connection between a center support and a Z-beam of
FIG. 3.
FIG. 9 shows a storage system having a net for holding the items
stored.
FIG. 10 shows a storage system having a retractable shade for
hiding the contents of the storage system.
FIG. 11 shows a storage system storing items.
FIG. 12 shows a storage system mounted above the rails of a garage
door.
FIG. 13 shows an expandable beam used to make a storage system
having at least one adjustable dimension.
FIG. 14 shows an alternative expandable beam used to make a storage
system having at least one adjustable dimension.
FIG. 15A shows a bottom perspective view of another preferred
embodiment of the invention.
FIG. 15B shows a bottom perspective view of another preferred
embodiment of the invention.
FIG. 16 shows another preferred embodiment of the present invention
where the storage system is generally triangular in shape.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
FIG. 1 shows a preferred suspended storage structure 100 including
a shelf or deck 102 which can be, for example, a welded wire mesh,
as shown, or a solid sheet, such as plywood, metal, or plastic.
Deck 102 is supported by beams 106 that form a rectangular frame
108. A preferred embodiment uses four beams 106, two longitudinal
beams (a front beam and a back beam) and two transverse side beams.
Beams 106 are suspended from vertical supports, which preferably
comprise a lower vertical corner support 110 and an upper vertical
corner support 112. Beams can be formed from steel or any other
appropriate material, preferably with a thickness of at least 16
gauge. The vertical supports shown in FIG. 1 comprise L-shaped
supports mounted on each corner of deck 102. Preferably, the
vertical supports are formed from steel or another appropriate
material with a thickness of at least 12 gauge or, more preferably,
10 gauge. Skilled persons will recognize that vertical supports
with a different cross-section shape can be used, for example a
flat or rectangular cross-section. Further, the vertical supports
can be mounted at locations other than the corners of deck 102 as
long as the deck is adequately supported.
FIG. 2 shows that upper and lower vertical corner supports 110 and
112 are preferably L-shaped, with sides of approximately equal
width. Each lower vertical corner support 110 has two keyhole
shaped slots 202 toward the lower end on each of the outer sides of
the vertical corner support 110. Deck 102 preferably does not
extend past frame 108, thereby eliminating weaker cantilevered deck
portions and facilitating the side-by-side placement of multiple
storage structures 100. Vertical corner supports are preferably,
but not always, constructed in two parts, such as upper part 112
and lower part 110, so that a user can adjust the height of the
supports by overlapping different amounts of the upper and lower
parts. The two parts can be connected using bolts, or other means,
such as interlocking slots on one piece and protrusions on the
other piece. For example, in one embodiment, the length of the
combination of vertical corner supports 110 and 112 can be adjusted
to be between 20 inches and 38 inches in 11/2-inch increments. The
holes in upper part 112 have appropriate shapes for the connectors,
for example, round holes if bolts are used, or key hole slots for
connecting to protrusions in the mating members. The shape of the
holes need not match the shape of the connectors exactly, for
example oval holes could be used with bolts to allow for more
adjustability.
FIG. 3 shows one preferred shape for beams 106. A preferred beam
106 comprises a 14-gauge steel, 21/2-inch wide, heavy-duty steel
Z-shaped beam. (The term "Z-shaped" as used herein is not limited
to beams having two horizontal and one angled portion between them
like the letter "Z", but includes any beam having a cross section
with multiple portions including an angled portion that is not
substantially perpendicular to a connected portion.) The Z-shaped
beams 106 include a horizontal portion 302 and a first vertical
portion 304 that extends upward from one end of the horizontal
portion 302. As shown in FIG. 3, deck 316 rests upon horizontal
portion 302, while butting up against the bottom of vertical
portion 304. In some embodiments, the top of vertical portion 304
can extend above deck 316. An angled portion 306 extends from the
end of horizontal portion 302 opposite to that of vertical portion
304 downwardly and toward the plane of vertical portion 302. Below
horizontal surface 302 and above angled portion 306 is a space
referred to as indentation 308. A second vertical portion 310
extends from angled portion 306 downwardly in approximately the
same plane of first vertical portion 302. In some embodiments in
which storage system 100 will support extra weight, additional
support can be provided by an addition horizontal portion 312 that
provides additional strength to beams 106. FIG. 3 shows a solid
deck 316, as an alternative to the wire deck 102 of FIG. 1,
supported on the top surface of the horizontal portion 302 of beam
106.
The invention is not limited to the beam configurations shown in
FIG. 3. For example, FIGS. 4A and 5A show alternative
configurations, an L-shaped beam 402 and a C-shaped beam 502,
respectively, both used with a solid deck 316. When such
alternative configurations are used, additional brackets (not
shown) can optionally be used to fix the position of deck 102.
FIGS. 4B and 5B show additional alternative configurations, an
L-shaped beam 402 and a C-shaped beam 502, respectively, both used
with a wire deck 102.
At each end of each of the four beams 106 are connectors for
connecting each beam 106 to a mating connector on the corresponding
vertical support 110. A preferred connector does not require an
assembler to use a screwdriver or wrench to connect threaded
fasteners, thereby facilitating assembly by "do-it-yourself"
homeowners. In one embodiment, the connector consists of a post 320
(FIG. 3) and a round flat plate 322 positioned at the end of post
320 and having a diameter larger than that of post 320. The plate
is inserted into the large-diameter portion of keyhole 202 (FIG. 2)
of vertical corner support 110, and then beam 106 is moved downward
until post 320 seats in the narrow end of keyhole slot 202. In a
preferred embodiment, a rivet forms post 320 and flat plate 322.
Other types of connectors could be used, and the keyhole could be
positioned on beams 106, with the rivets on vertical corner
connectors 110. In another embodiment, the connectors could be
located on the inner surface of the beams so that the vertical
supports are located inside the frame. If necessary, deck panels
could be notched to accommodate the interior vertical supports.
One or more ribs 120 (FIG. 1) typically provide support for deck
102. FIG. 6 shows a cross section, taken as shown by the lines 6-6
of FIG. 1, of a preferred rib 120 for use with a wire deck 102. Rib
120 preferably comprise a V-shaped center portion 602 that provides
strength for supporting a load away from the frame 108 and flat end
portions 604 that provide additional support for a wire deck 102
near frame 108. The opening of the "V" preferably faces the wire
deck 102 to provide more contact area, and the top of the "V" can
be flanged to provide a horizontal lip for even more contacting
area. The V-shape resists bending along the span between opposing
beams 106. Other cross-sectional shapes for the ribs could be used
including U-shaped or square. The wires of wire deck 102 typically
form a grid pattern, and flat end portions 604 preferably extend
away from the frame beyond the end of the first row in the grid,
thereby providing broad support for at least the first wire that is
away from the frame 108 and that is transverse to the long axis of
rib 120. The grid pattern of wire deck 102 can include rectangles
(including squares. i.e., rectangles having sides of equal length),
diamonds, or other utilitarian or decorative patterns.
Preferably, at least some, and more preferably all, of the wires
forming wire deck 102 are bonded to ribs 120, preferably by
welding. Bonding the wire deck 102 to the ribs creates a stronger,
more rigid deck structure that can support a great deal of weight
without sagging. Each of the wires crossing ribs 120 is preferably
welded to the rib.
In various embodiments, decks 102 are 4 ft.times.2 ft, 4 ft.times.4
ft, 6 ft.times.2 ft, 6 ft.times.4 ft, 8 ft.times.2 ft and 8
ft.times.4 ft, and can made in 3 ft.times.2 ft or 4 ft.times.2 ft
sections or deck panels, each deck panel including 2 support ribs
120 to which the wires in the deck panel are welded. In some
embodiments, decks 102 are 4 ft.times.3 ft, 6 ft.times.3 ft and 8
ft.times.3 ft and are made, for example, in 4 ft.times.3 ft or 3
ft.times.2 ft deck panel, with each deck panel having 2 ribs.
Referring also to FIGS. 15A and 15B, in one 2 ft by 8 ft embodiment
shown in, the deck 102 is preferably composed of two 2 ft by 4 ft
welded wire deck panels 1503 and 1505, with two 4 ft support ribs
120 running under each panel. Wires from both panels are welded to
the two corresponding support ribs. A 2 ft. cross support 121 runs
between the two panels and supports the ends of ribs from each
panel. The cross support preferably includes clips (not shown) for
attaching the wires from both panels.
Beam 106 can optionally include multiple L-clips 702 as shown in
FIG. 7. L-clips 702 are positioned on beams 106 to maintain wire
deck 102 in position. L-clips 702 are preferably attached by
welding or by threaded fasteners. The vertical portion of L-clips
702 preferably extends vertically to about the same height as the
vertical portion 304 of beam 106 to prevent deck 102 from being
displaced under load.
In embodiments that support a heavier load, additional support can
be provided by center supports 130 (FIG. 1), which can be attached
between the ceiling and beams 106. The term "center support"
includes any supports positioned between the corner supports 110
and is not limited to supports positioned half way between the
corner supports 110. Center supports 130 can preferably be
positioned wherever desired along the length of beams 106 to
provide additional support where the load is heaviest or to
coincide with building structure in the ceiling, such as ceiling
joists. In some embodiments, two center supports are used, one
attached to the front beam 106 and one attached to the rear beam
106. Additional center supports can be added to accommodate a
heavier load. In embodiments that support heavier loads, the beams
and vertical supports (including center supports) can be formed
from thicker gauge material. For example, vertical supports can be
at least 10 gauge and beams can be greater than 14 gauge. As
discussed above and shown in FIG. 3, additional weight-bearing
support for the beams can also be provided by an addition
horizontal portion 312 that provides additional strength to beams
106.
FIG. 8 shows that a typical center support 130 includes a top
vertical portion 801 to which are attached one or two L-shaped
brackets 804 for attaching to a ceiling joist or other structural
component (not shown). Center support 130 also includes a bottom
portion 802 attached to upper portion 801 using threaded fasteners
or other means such as interlocking slots. Bottom portion 802
includes a bent portion 806 that fits into the indention 308 in
beam 106 to provide support to beam 106. Bent portion 806
preferably extends into indentation 308 until it touches or almost
touches angled portion 306 of beam 106. A bolt 812 clamps vertical
portion 304 of beam 106 between a square plate 810 and bottom
portion 802 of center support 130 to secure center support 130 to
beam 106. A spacer 814 fills the gap between portion 802 and plate
810 near the bolt location. An L-clip 702 (FIG. 7) is preferably
positioned below bolt 812, and the bolt or an its associated
hardware, such as a lock-washer, extends deck over a wire from wire
deck 102 to trap the wire between the L-clip and the bolt or its
hardware, thereby prevented wire deck 102 from coming off of its
support structure without removal of the bolt.
Because the attachment of center support 130 to beam 106 does not
require a hole in beam 106 at the point of attachment, center
support 130 can be attached anywhere along the length of beam 106,
and the position is not limited by the location of holes in beam
106. The position at which center support 130 is attached can be
varied by the end user depending on the load distribution and on
the position of ceiling structural members, such as ceiling joists.
The center support is preferably positionable at any point along a
continuous portion of the beams 106, meaning that the position
along the beam is not limited by the location of holes in the beam,
although there may still be specific points along the length of
beam 106 at which the center support cannot be positioned because
of interfering structural features. Also, because no holes are
necessary in beam 106, the beam is stronger and can support
additional weight without requiring a larger, heavier beam.
Thus, the present invention provides great flexibility. For
example, in some embodiments, if heavier items are loaded toward
one end of deck 102, additional center support brackets 130 can be
used to provide additional support. In some embodiments, additional
deck ribs 120 can also be added in that area to shore up the deck.
In other embodiments, one or more center supports can be used to
replace some or all of the fixed vertical supports discussed above.
Skilled persons will recognize that in these embodiments the center
supports can be mounted at the corners of the deck or at other
positions as long as the deck is adequately supported.
The upper end of corner supports 112 (FIG. 1) are preferably
attached to L-shaped ceiling brackets 140, which are attached to a
building structure, such as ceiling joists, trusses, or beams,
preferably wooden beams or metal joists. Brackets 140 are typically
bolted onto the upper vertical corner support 112, and the other
arm of the L-shaped bracket 140 is then attached using screws or
other fastening devices to a building structural component. Slots
in the bracket 140 provide some adjustment for aligning the
brackets with building structural components. Bracket 140 can be
attached to either face of support 112, so that bracket 140 can be
oriented parallel to the building structural component to
facilitate attachment. Ceiling brackets 140 can be of any desired
length, for example the brackets can be long enough to span and be
mounted to several ceiling joists.
FIG. 9 shows that holes or brackets in the corner brackets 110 can
be used to support a net 900 or other structure that keeps items on
deck 102 from falling off. FIG. 10 shows that a shade 1002 can be
mounted on a ceiling 1004 or on brackets 110 of storage system 100.
FIG. 9 shows the shade about three-quarters of the way down.
Multiple shades 1002 can be pulled down to hide the contents of
storage system 100. Each shade 1002 includes a magnetic strip 1008
to hold the bottom of the shade in place against beam 106.
Mechanical clips or hooks could also be used to keep the drawn
shade in place.
Storage system can be made in various sizes, and the number of
center supports 130 and deck support ribs 120 can be varied with
the overall size of the unit and the weight to be carried. Because
deck 102 preferably does not extend past frame 108, multiple
storage units 100 can be positioned next to each other, with the
frames juxtaposed. The L-shaped vertical corner supports facilitate
bolting units together on any side. Combining units increases the
overall storage area by allowing an end user to create a loft
composed of several systems.
FIG. 11 shows a typical storage system 100 with items stored
thereon. Some embodiments of the storage system, such as that shown
in FIG. 12, are suitable for mounting above the rails of a sliding
overhead garage door, thereby making additional storage space
available. While suitable for use in a residential garage, the
invention is not limited to such use, and can be used wherever
overhead storage is desired.
FIG. 13 shows an alternative embodiment in which beams 106 can be
configured in two parts that slide into one another, to make a
system having an adjustable length and/or width. One beam 106
includes two slots 1302, one in the top portion 304 and one in the
lower portion 310. The other beam includes near its end holes 1306
for a connector that can be secured with nuts or a threaded backing
plate to keep the beam sections together. Suitable connectors can
include, for example, bolts passing through both beams, permanent
rivets at predetermined locations or slidable rivets on the first
beam. Clamps such as those shown in FIG. 14 below can also be used
to hold the beams together. FIG. 14 shows an alternative embodiment
in which beams 106 can be configured in two parts that slide into
one another, to make a system having an adjustable length and/or
width. Two clamps 1402 including bolts 1404 hold the two beams 106
together. In some embodiments, each clamp 1402 will include 2
bolts, one positioned near the top and one near the bottom of each
clamp, to press against vertical surfaces 304 and 310,
respectively.
Embodiments of the invention that use a Z-beam frame and a wire
deck welded to support ribs provide a very stable, sturdy structure
that is relatively light weight, so that more of the load bearing
capacity of the building structural component is available for
useful load. The adjustable center supports used in some
embodiments spread the load on the building component, thereby
increasing the maximum capacity. In many case, the inventive system
is so strong that the maximum load of an installed system is
limited not by the strength of the system itself, but by the load
bearing capacity of the building structural components to which the
system is attached. For example, one embodiment of a four foot by
eight foot system that uses 8 deck rib supports and four center
beam supports, two along the front beam and two along the rear
beam, can support 1000 pounds or more, although a lighter load is
recommended if the structure is suspended from ceiling joists of a
residential garage. Some smaller embodiments, such as those having
a maximum dimension of four feet or less, may not include center
supports. Embodiments that are six feet typically use two center
supports. Whether or not center supports are used in any embodiment
will depend on the load to be carried.
Table 1 below is a table that describes various embodiments.
TABLE-US-00001 TABLE 1 No. of Maximum Sliding Wire Deck Load
Capacity Approx Center Panels Rib Deck Residential Size Weight
Supports (Size in Supports (Structural) (Feet) (Pounds) (Quantity)
feet) (Quantity) (Pounds) 4 .times. 2 35 0 1 (4 .times. 2) 2 400
(600) 4 .times. 3 45 0 1 (4 .times. 3) 2 400 (600) 4 .times. 4 50 0
2 (4 .times. 2) 4 500 (700) 6 .times. 2 60 2 2 (3 .times. 2) 4 + 1
600 (1000) center rib 6 .times. 3 65 2 3 (3 .times. 2) 6 600 (1000)
6 .times. 4 75 2 3 (4 .times. 2) 6 600 (1000) 8 .times. 2 80 2 2 (4
.times. 2) 4 + 1 600 (1000) center rib 8 .times. 3 85 2 4 (3
.times. 2) 8 600 (1000) 8 .times. 4 90 2 4 (4 .times. 2) 8 600
(1000)
FIG. 15A shows another preferred embodiment of the present
invention. In FIG. 15, suspended storage structure 1500 includes a
rectangular shelf or deck 1502 formed by positioning two
substantially square deck panels 1503 and 1505 side by side. The
deck panels can be, for example, a welded wire mesh, as shown, or a
solid sheet, such as plywood, metal, or plastic. Deck 1502 is
supported by transverse beams 1507 and longitudinal beams 1506 that
form a rectangular frame 1508. Transverse beams 1507 do not extend
lengthways past the lateral edges of deck 1502. Longitudinal beams
1506 extend to the outside edges of transverse beams so that
transverse beams 1507 are butted up against the interior surface of
longitudinal beams 1506. The corresponding lateral ends of
transverse beams 1507 and longitudinal beams 1506 can be attached,
for example, by an L-shaped bracket 1509 welded or otherwise
attached to the outside corner formed by the two beams. Transverse
beams 1507 are suspended from vertical supports 1510. One or more
ribs 120 provide support for each deck panel. Cross support 121
runs between the two panels and supports the ends of ribs from each
panel.
The vertical supports shown in FIG. 15A comprise supports mounted
near each corner of deck 1502. The vertical supports do not have to
be mounted directly at the corners of the frame. Instead, the
mounting position can be varied to allow, for example, the location
of the vertical supports to match the location of ceiling joists,
or to allow for a larger opening between supports so that larger
objects can be stored on the shelf. In some embodiments, vertical
supports can be flat bar steel (or other appropriate material)
rather than the L-shaped steel supports discussed above in order to
reduce manufacturing costs.
FIG. 15B shows another preferred embodiment of the present
invention. In FIG. 15B, deck panels 1503 and 1505 are positioned
side by side and supported by longitudinal beams 1506 supporting
both deck panels 1503 and by transverse beams 1507 each supporting
only one panel. Longitudinal beams 1506 are suspended from vertical
supports 1510. The vertical supports shown in FIG. 15B comprise
supports mounted near each end of longitudinal beams 1506.
All configurations and dimensions described above are by way of
example only, and the invention is not limited to any specific
dimension or configuration of the novel aspects. Skilled persons
will recognize that many brackets can be used on the ends of beams
and support structures to facilitate connection, so when applicant
states that one part is connected to another part, it is understood
that the connection does not need to be immediate and such
connection does not exclude the use of intermediary brackets.
While rectangular and square decks have been described, the
invention is not limited to any particular shape of deck. As shown
in FIG. 16, the invention could be used for a triangular storage
system for mounting in a corner, the system including three beams
instead of four, and the internal angles of some of the support
brackets being less than ninety degrees. FIG. 16 shows a triangular
storage system 1601 using three parallel support ribs 120 oriented
perpendicular to the front edge of the triangular deck frame 1602.
For applications where less support is needed, only one support rib
can be used, preferably oriented perpendicular to the front edge
1610 of the triangular deck frame 1602 and running from the back
corner 1612 to the front edge 1610.
As used herein, the term "L-shaped" does not exclude a shape in
which the two sides of the "L" have equal length or a shape in
which the angle of intersection between the arms varies from ninety
degrees. Also, as used herein, the term "rectangle" includes a
square. Further, as used herein the term "deck" can refer to a deck
formed as one unit or formed from multiple smaller deck panels.
Although the present invention and its advantages have been
described in detail, it should be understood that various changes,
substitutions and alterations can be made herein without departing
from the spirit and scope of the invention as defined by the
appended claims. Moreover, the scope of the present application is
not intended to be limited to the particular embodiments of the
process, machine, manufacture, composition of matter, means,
methods and steps described in the specification. As one of
ordinary skill in the art will readily appreciate from the
disclosure of the present invention, processes, machines,
manufacture, compositions of matter, means, methods, or steps,
presently existing or later to be developed that perform
substantially the same function or achieve substantially the same
result as the corresponding embodiments described herein may be
utilized according to the present invention. Accordingly, the
appended claims are intended to include within their scope such
processes, machines, manufacture, compositions of matter, means,
methods, or steps.
* * * * *
References